典型黑土区不同水土保持林表层土壤磷素形态及有效性

以典型黑土区人工营造的落叶松林、水曲柳林、樟子松林和美青杨林表层土壤(0～10 cm)为对象,研究不同类型水土保持林土壤磷素的形态和有效性.结果表明: 水曲柳林和美青杨林土壤全磷、速效磷和磷各组分含量均显著高于落叶松林和樟子松林;4种林地土壤磷主要以有机磷形式存在,并且中活性有机磷NaOH P_o含量最高,占土壤磷素总量的58.9%;对植物有效性相对较高的H₂O P_i和NaHCO₃ P含量较低,分别占土壤磷素总量的1.2%和6.6%;除NaHCO₃ P_o外,土壤中不同磷素形态之间以及磷各组分与土壤有机质、全磷和有效磷之间具有显著相关关系.表明研究区内阔叶林比针叶林能够显著地提高土壤磷的有效性.     

不同类型城市森林对土壤肥力的影响

以东北林业大学城市林业示范研究基地中9种人工林(兴安落叶松林、樟子松林、黑皮油松林、黄波罗林、胡桃楸林、水曲柳林、白桦林、蒙古栎林、针阔混交林)及附近的农耕地和撂荒地土壤为研究对象,通过对林地土壤不同层次pH值、有机质及主要养分含量的测定分析,研究了不同林型对土壤肥力的影响.结果表明：阔叶林(除蒙古栎林)的土壤趋于中性,针阔混交林、兴安落叶松林、樟子松林和黑皮油松林的土壤呈微酸性,蒙古栎林的土壤呈酸性;随土壤深度增加,土壤有机质、水解氮、速效钾、有效磷、全氮、全磷含量均呈下降趋势.不同林地土壤同一层次化学指标整体差异显著(P＜0.05).土壤肥力优劣为：水曲柳林>黄波罗林>针阔混交林>胡桃楸林>白桦林>撂荒地>农耕地>樟子松林>兴安落叶松林>蒙古栎林>黑皮油松林,说明阔叶林(除蒙古栎林)和针阔混交林中的土壤肥力增加,而针叶林的土壤肥力趋于下降.     

大兴安岭典型永久冻土土壤细菌群落组成和多样性

【背景】土壤微生物是土壤生物中的重要成分,参与了土壤生态系统中关键的生物化学循环过程。但是关于寒温带多年冻土土壤微生物的研究还比较薄弱。【目的】探究大兴安岭多年冻土土壤中微生物的多样性和种群结构。【方法】利用MiSeq高通量测序技术对黑龙江大兴安岭地区呼中保护区落叶松冻土和樟子松林冻土土壤样品进行测序。【结果】在落叶松冻土和樟子松林冻土土壤中,相对丰度最高的优势菌群的组成基本一致,在门水平有疣微菌门(Verrucomicrobia)、变形菌门(Proteobacteria)、酸杆菌门(Acidobacteria)、浮霉菌门(Planctomycetes)、绿菌门(Chlorobi)、Parcubacteria、放线菌门(Actinobacteria)、拟杆菌门(Bacteroidetes)、厚壁菌门(Firmicutes)、芽单胞菌门(Gemmatimonadetes)10个细菌门类,其中,疣微菌门(Verrucomicrobia)在樟子松林土壤中的相对丰度较多,变形菌门(Proteobacteria)在落叶松林土壤中的相对丰度较多。通过α多样性分析可知,落叶松冻土土壤微生物的群落多样性高于樟子松林冻土,而且两者的细菌群落组成与结构差异性较大。【结论】为深入认识大兴安岭多年冻土区的土壤微生物群落结构组成以及影响因素提供数据支撑。     

大兴安岭北部天然针叶林土壤氮矿化特征

采用顶盖埋管法对大兴安岭地区天然针叶林(樟子松林、樟子松-兴安落叶松混交林和兴安落叶松林)土壤铵态氮(NH~+_4-N)、硝态氮(NO~-_3-N)、净氮矿化速率进行研究,并探索土壤理化性质与氮矿化之间的相关性,为大兴安岭地区森林生态系统土壤养分管理及森林经营提供帮助。结果表明:观测期内(5—10月)3种林型土壤无机氮变化范围为31.51—70.42 mg/kg,以NH~+_4-N形式存在为主,占比达90%以上,且与纯林相比混交林土壤无机氮含量较高。3种林型土壤净氮矿化、净氨化、净硝化速率月变化趋势呈V型,7、8月表现为负值,其他月份为正值。净氮矿化速率变化范围樟子松林为-0.54—1.28 mg kg~(-1) d~(-1)、樟子松-兴安落叶松混交林为-0.13—0.55 mg kg~(-1) d~(-1)、兴安落叶松林为-0.80—1.05 mg kg~(-1) d~(-1)。土壤净氨化过程在土壤氮矿化中占主要地位,占比达60%以上。3种林型土壤净氮矿化、净氨化及净硝化速率垂直差异显著,0—10 cm土层矿化作用明显高于10—20 cm土层(P0.05)。土壤氮矿化速率与土壤含水量、土壤有机碳含量、土壤C/N、枯落物全氮含量和枯落物C/N均存在显著相关性。不同类型的森林土壤及枯落物的质量也存在差异,进而影响土壤氮矿化特征。     

中国东部主要松林营养元素循环的比较研究

 中国的松林主要分布在亚热带和温带地区,在亚热带和温带地区东部主要是马尾松林、华山松林、油松林、红松林和樟子松林。松林由于树种、起源和年龄的差别,其生物量的变化幅度较大,在65～200t·hm-2之间(东北地区的原始红松林最高生物量可达360t·hm-2),松林的生物量表现出区域分异的特点。即从南到北随着纬度的增加,林分的生物量有逐渐降低的趋势。松树针叶中5种主要营养元素含量表现为[N]>[K]≥[Ca]>[Mg]≥[P],而且营养元素表现出因种而异,N的含量为华山松≥马尾松>油松≥红松>樟子松,而P和K在油松和红松针叶中含量较高;Ca的含量表现出较大的波动,与其母岩关系密切。松林主要营养元素(N、P、K、Ca、Mg)的积累量中N一般占25％～40％,松林营养元素循环速率受生境,树种、年龄的影响,但总的来说,亚热带地区松林营养元素的循环速率高于温带地区松林。     

哈尔滨市不同类型人工林土壤重金属含量

以东北林业大学城市林业示范研究基地9种人工林(兴安落叶松林、樟子松林、黑皮油松林、黄波罗林、胡桃楸林、水曲柳林、白桦林、蒙古栎林和针阔混交人工林)为对象,分析林地土壤不同层次(0～10 cm和10-30 cm)A8、Cd、Cu、Ni、Pb、Zn 6种重金属含量,并以哈尔滨市土壤背景值为标准,采用综合污染指数法评价各林型土壤重金属污染状况.结果表明:不同类型人工林同一土层重金属含量差异显著;除了As和Ni,同一人工林土壤重金属含量均随土壤深度增加呈下降趋势.各类型人工林同一土层重金属含量以Zn最高(62.29～126.35mg·kg-1),Cd最低(0.06～0.47 mg·kg-1).6种重金属含量由高到低顺序为:Zn＞Pb＞Cu(Ni)＞Ni(Cu)＞As＞Cd,累积程度为:Cd＞Pb＞Zn＞Cu＞Ni＞As.林地土壤Pb、Cd、Cu、Zn间(除水曲柳林)及其与土壤有机质、N、P、K(除水曲柳林和蒙古栎林)显著相关,且以上4种重金属含量高于背景值,为人为输入;Ni和As含量与本地背景值相当,为自然因素,不同林型土壤内梅罗综合污染指数依次为:水曲柳林＞黄波罗林＞针阔混交林＞胡桃楸林＞樟子松林＞黑皮油松林＞兴安落叶松林＞白桦林＞蒙古栎林.     

不同密度樟子松人工林土壤碳氮磷化学计量特征

以科尔沁沙地不同密度(490、750、1550、1930、2560株·hm-2)樟子松人工林(栽植于1980年)为研究对象,分析林分密度对土壤碳、氮、磷浓度及其计量比的影响,研究林分密度与土壤养分状况的关系。结果表明:随着樟子松林密度增加,各土层(0～10、10～20和20～40 cm)土壤有机碳、全氮、全磷浓度和C∶N呈先增加后降低趋势,而土壤有效磷浓度呈先降低后增加趋势。土壤有机碳浓度在490株·hm-2密度小于其他密度,而有效磷浓度大于其他密度;土壤C∶P和N∶P在2560株·hm-2密度显著大于其他密度。各密度樟子松林土壤有机碳、全氮、全磷和有效磷浓度在0～10 cm土层显著大于10～20和20～40cm土层,樟子松人工林土壤养分具有表聚性。通过典范对应分析发现,密度对樟子松林土壤养分影响的主要因子是土壤有机碳、全氮和全磷,且密度为1550株·hm-2时土壤有机碳、全氮、全磷和碱解氮浓度较高,而C∶P和N∶P较低。因此,当樟子松人工林密度为1550株·hm-2时,土壤养分浓度较高,林木生长较好,为最佳经营密度。     

不同密度樟子松人工林土壤碳氮磷化学计量特征

以科尔沁沙地不同密度(490、750、1550、1930、2560株·hm-2)樟子松人工林(栽植于1980年)为研究对象,分析林分密度对土壤碳、氮、磷浓度及其计量比的影响,研究林分密度与土壤养分状况的关系。结果表明:随着樟子松林密度增加,各土层(0～10、10～20和20～40 cm)土壤有机碳、全氮、全磷浓度和C∶N呈先增加后降低趋势,而土壤有效磷浓度呈先降低后增加趋势。土壤有机碳浓度在490株·hm-2密度小于其他密度,而有效磷浓度大于其他密度;土壤C∶P和N∶P在2560株·hm-2密度显著大于其他密度。各密度樟子松林土壤有机碳、全氮、全磷和有效磷浓度在0～10 cm土层显著大于10～20和20～40cm土层,樟子松人工林土壤养分具有表聚性。通过典范对应分析发现,密度对樟子松林土壤养分影响的主要因子是土壤有机碳、全氮和全磷,且密度为1550株·hm-2时土壤有机碳、全氮、全磷和碱解氮浓度较高,而C∶P和N∶P较低。因此,当樟子松人工林密度为1550株·hm-2时,土壤养分浓度较高,林木生长较好,为最佳经营密度。     

沙地樟子松带状混交林土壤碳氮磷化学计量特征

探究不同沙地樟子松混交林土壤碳氮磷化学计量变化规律,为其混交经营提供科学依据.以沙地樟子松纯林为对照,在沙地樟子松×榆树及沙地樟子松×怀槐带状混交林中,沿沙地樟子松和伴生树种两个方向在距离混交中心0、1、2、3和4 m处的不同土层采集土样,分析土壤有机C、全N、全P、速效N、速效P含量及其计量比的特征.结果表明: 沙地樟子松混交林土壤有机C、全N和速效N含量高于纯林, 沙地樟子松与榆树混交主要增加了深层土壤有机C和全N含量,以及C/N和C/P, 沙地樟子松与怀槐混交提高了土壤N含量, 降低了P含量.随着远离混交林中心,沙地樟子松×榆树混交林中沙地樟子松林带的土壤C/N先升高后降低,全P和速效P含量下降,N/P增加;榆树林带土壤C/N下降,速效P含量先升高后降低.沙地樟子松×怀槐混交林土壤全N含量在沙地樟子松林带先降低后升高,在怀槐林带先升高后降低.沙地樟子松混交林提高了土壤C、N储量,沙地樟子松应与榆树行间混交,与怀槐间隔2行混交.     

基于器官-凋落叶-土壤生态化学计量特征的樟子松和赤松人工林养分利用策略

以科尔沁沙地樟子松与赤松人工林为对象,分析不同器官、凋落叶和土壤的C、N、P化学计量,比较研究两个树种的养分保存与利用机制。结果表明：樟子松叶C含量及C∶N、C∶P和N∶P、枝N含量以及根N和P含量显著高于赤松,而叶P含量、枝C∶N、根C含量及C∶N和C∶P显著低于赤松。樟子松N和P含量随枝叶年龄增加而下降,而赤松P含量表现为当年和二年生枝叶显著高于一年生枝叶。樟子松凋落叶C、N、P含量均显著高于赤松,C∶P和N∶P显著低于赤松。赤松叶片P重吸收效率显著高于樟子松,并且两个树种的P重吸收效率显著高于N重吸收效率。樟子松林土壤P含量显著低于赤松林,而C∶N和C∶P显著高于赤松林。樟子松养分主要供给新生组织器官,而老年枝叶的养分保存能力下降,凋落叶更易于分解,不利于土壤养分保存,土壤P含量较低。赤松养分保存能力更强,通过维持较高养分重吸收效率,提高体内养分利用效率,降低对土壤P的消耗。     

内蒙半干旱低山区不同纯林土壤腐殖质分异特征及其与其他生物化学性质的关系

纯林土壤腐殖质含量及其构成是否会因枯落叶组成的单一性和单优群落环境的特殊性而发生分异变化是关系到森林可持续经营的关键问题.本文以内蒙半干旱低山区的6种典型纯林为研究对象,研究了不同树种纯林土壤腐殖质分异特征及其与其他生物化学性质的关系.结果表明：云杉和白桦林地土壤的腐殖质含量、缩合程度和稳定性均较高,其次为小叶杨和落叶松林地,再次为白榆林地,而油松林地土壤的腐殖质含量和缩合程度均最低、稳定性最差.土壤微生物生物量和磷酸酶活性与腐殖质各组分的积累及其稳定性存在相互促进作用;过氧化氢酶和脱氢酶活性则与土壤腐殖质存在相互抑制作用,且脱氢酶活性的提高可能破坏腐殖质的稳定性.速效N含量与腐殖质积累及其稳定性呈正相关,而全量Cu、Fe、Zn含量与腐殖质呈负相关,全Cu、Fe的增加可能会破坏腐殖质的稳定性.纯林环境及其枯落叶性质的特殊性是造成腐殖质分异的重要原因,混交改造或增加林下植被是改善土壤腐殖质构成的根本措施.     

半干旱黄土丘陵区纯林土壤腐殖质异化特征及与其他性质的关系

纯林长期生长或多代连栽必然会导致土壤腐殖质含量和构成发生异化,探究这种异化特征及其与土壤其他性质的关系可以为纯林管理或混交改造提供科学依据。通过对半干旱黄土丘陵区南泥湾林场8种典型纯林土壤腐殖质及其他性质进行系统检测,结果表明:(1)侧柏林土壤腐殖质含量最高(34.61 g/kg),腐殖化程度和稳定性一般;白榆和白桦林土壤的腐殖质含量中等(19.69—23.58 g/kg)、腐殖化程度和稳定性最佳;茶条槭和小叶杨林土壤的腐殖质含量(20.59—22.53 g/kg)和构成均为中等水平;油松、沙棘和刺槐林土壤的腐殖质质量较低(11.77—13.81 g/kg),且腐殖化程度较低,稳定性相对最差;(2)与胡敏酸含量存在显著相互促进作用(P0.05)的土壤性质为CEC、N、微生物量和蛋白酶活性(相关系数0.769—0.926,下同),存在显著相互抑制作用的为有效Cu(-0.793);与富啡酸存在显著相互促进作用的为N、CEC、微生物量、蔗糖酶和磷酸酶活性(0.836—0.955),存在显著相互抑制作用的为有效Cu(-0.822);与胡敏素存在显著相互促进作用的为N、CEC、微生物量、磷酸酶活性和有效Zn(0.766—0.951),存在显著相互抑制作用的为脱氢酶活性(-0.784)。(3)腐殖质构成与其他性质的相关性均不显著(P0.05),其中相对有利于提高胡敏酸/腐殖酸含量之比的土壤性质为蛋白酶、蔗糖酶和过氧化氢酶活性,而不利的是脱氢酶活性;相对有利于提高胡敏酸/富啡酸含量之比的为速效K、CEC和脲酶活性,而不利的是脱氢酶活性。(4)总体而言土壤腐殖质含量较之腐殖质构成与其他性质之间具有更大的相关性;向土壤增施N肥可以促进腐殖质的形成,增加K肥则有利于腐殖质构成的改善,而通过混交改造或增加林下植被是促进纯林土壤腐殖质化过程和解决土壤退化的根本措施。     

A Functional and Structural Mongolian Scots Pine (Pinus sylvestris var. mongolica) Model Integrating Architecture, Biomass and Effects of Precipitation

Mongolian Scots pine (Pinus sylvestris var. mongolica) is one of the principal tree species in the network of Three-North Shelterbelt for windbreak and sand stabilisation in China. The functions of shelterbelts are highly correlated with the architecture and eco-physiological processes of individual tree. Thus, model-assisted analysis of canopy architecture and function dynamic in Mongolian Scots pine is of value for better understanding its role and behaviour within shelterbelt ecosystems in these arid and semiarid regions. We present here a single-tree functional and structural model, derived from the GreenLab model, which is adapted for young Mongolian Scots pines by incorporation of plant biomass production, allocation, allometric rules and soil water dynamics. The model is calibrated and validated based on experimental measurements taken on Mongolian Scots pines in 2007 and 2006 under local meteorological conditions. Measurements include plant biomass, topology and geometry, as well as soil attributes and standard meteorological data. After calibration, the model allows reconstruction of three-dimensional (3D) canopy architecture and biomass dynamics for trees from one- to six-year-old at the same site using meteorological data for the six years from 2001 to 2006. Sensitivity analysis indicates that rainfall variation has more influence on biomass increment than on architecture, and the internode and needle compartments and the aboveground biomass respond linearly to increases in precipitation. Sensitivity analysis also shows that the balance between internode and needle growth varies only slightly within the range of precipitations considered here. The model is expected to be used to investigate the growth of Mongolian Scots pines in other regions with different soils and climates.     

Characterization of Humus Microbial Communities in Adjacent Forest Types That Differ in Nitrogen Availability

To address the link between soil microbial community composition and soil processes, we investigated the microbial communities in forest floors of two forest types that differ substantially in nitrogen availability. Cedar-hemlock (CH) and hemlock-amabilis fir (HA) forests are both common on northern Vancouver Island, B.C., occurring adjacently across the landscape. CH forest floors have low nitrogen availability and HA high nitrogen availability. Total microbial biomass was assessed using chloroform fumigation-extraction and community composition was assessed using several cultivation-independent approaches: denaturing gradient gel electrophoresis (DGGE) of the bacterial communities, ribosomal intergenic spacer analysis (RISA) of the bacterial and fungal communities, and phospholipid fatty acid (PLFA) profiles of the whole microbial community. We did not detect differences in the bacterial communities of each forest type using DGGE and RISA, but differences in the fungal communities were detected using RISA. PLFA analysis detected subtle differences in overall composition of the microbial community between the forest types, as well as in particular groups of organisms. Fungal PLFAs were more abundant in the nitrogen-poor CH forests. Bacteria were proportionally more abundant in HA forests than CH in the lower humus layer, and Gram-positive bacteria were proportionally more abundant in HA forests irrespective of layer. Bacterial and fungal communities were distinct in the F, upper humus, and lower humus layers of the forest floor and total biomass decreased in deeper layers. These results indicate that there are distinct patterns in forest floor microbial community composition at the landscape scale, which may be important for understanding nutrient availability to forest vegetation.     

Soil macro-invertebrates and litter disappearance in a Japanese mixed deciduous forest and comparison with European deciduous forests and tropical rainforests

Soil macro-invertebrates and rate of litter disappearance were studied in a ridge plot with moder (mor) humus and a bottom plot with mull humus on a slope in a temperate mixed deciduous forest in Kyoto, Japan (J). The results were compared with those from two German beech forests (G) representative of European deciduous forest mor and mull. Between-plot differences in biomass of total saprophagous animals was much smaller in J than in G, which is dominated by earthworms. Susceptibility to soil acidity and zoogeographical distribution of earthworms were suggested to be related to this situation. Biomass of soil macro-invertebrates and litter turnover rate were compared among J, G and three types of tropical rainforests in Malaysia (M) in relation to climatic conditions. Taking into account among-site differences in temperature and moisture, which affect microbial activity and in biomass of saprophagous macro-invertebrates especially earthworms, the following order of importance of soil macro-invertebrates in determining the rate of litter disappearance was suggested: G>J>M. Based on the comparison of biomass of earthworms among European deciduous forests, Japanese deciduous forests and tropical rainforests, as well as on the presence or absence of anecic earthworms in these forests, it was suggested that this ranking could be generalized to European deciduous forests > Japanese deciduous forests > tropical rainforests. It was pointed out that this order was the opposite of the gradient in evapotranspiration rate existing among these regions.     

干旱胁迫对不同基质网袋桢楠幼苗生长及生物量的影响

探讨不同育苗基质下桢楠（Phoebe zhennan）苗木对周期性干旱胁迫的适应能力及生存对策,为筛选抗旱育苗基质提供参考。以耕作土、森林腐殖土、泥炭土、蛭石为原料,按体积比配制成5种育苗基质,T1：耕作土=10（传统桢楠育苗）、T2：森林腐殖土=10、T3：耕作土：森林腐殖土：泥炭土：蛭石=4：3：2：1、T4：耕作土：森林腐殖土：泥炭土：蛭石=3：2：4：1、T5：耕作土：森林腐殖土：泥炭土：蛭石=2：1：6：1,采用随机区组设置干旱胁迫梯度,分析不同胁迫水平对桢楠幼苗生长的影响。结果表明：（1）配比基质的理化性质与苗木生长密切相关,正常浇水时,基质处理苗生长质量均优于传统育苗,但重度胁迫下,仅T3、T4处理苗木生长较好;（2）随着干旱胁迫程度的增加,各基质配比桢楠苗木株高、基径、叶面积、叶面积指数、地上生物量、地下生物量等生长指标均受到抑制,但受影响程度存在差异;（3）各基质处理苗木质量隶属函数值T3 > T4=T1 > T2 > T5,T3基质配比最优,所育苗木生长优良,耐旱抗旱性强,显著提高造林成效。表明适宜的基质配比能够协调植物生长所需的水、肥、气、热,有利于植物在逆境中生存。     

Microbial biomass and growth kinetics of microorganisms in chernozem soils under different land use modes

The carbon content of microbial biomass and the kinetic characteristics of microbial respiration response to substrate addition have been estimated for chernozem soils under different land use: arable lands used for 10, 46, and 76 years, mowed meadow, natural forest, and forest shelter belt. Microbial biomass and the content of microbial carbon in humus (C_mic /C_org) decreased in the following order: soils under forest cenoses—mowed meadow—10-year arable land—46- and 75-year arable land. The amount of microbial carbon in the long-plowed horizon was 40% of its content in the upper horizon of natural forest. Arable soils were characterized by a lower metabolic diversity of microbial community and by the highest portion of microorganisms able to grow directly on glucose introduced into soil. The effects of different scenarios of carbon sequestration in soil on the amounts and activity of microbial biomass are discussed.     

Divergent biomass partitioning to aboveground and belowground across forests in China

Aims Belowground to aboveground biomass (BGB/AGB) ratio is a highly valued parameter of the terrestrial carbon cycle and productivity. However, it remains far from clear whether plant biomass partitioning to aboveground and belowground is isometric (equal partitioning) or allometric (unequal partitioning) at community levels and what factors are necessary in order to regulate the partitioning. This study aimed to comprehensively find out the patterns of biomass partitioning and their regulatory factors across forests in China.Methods The data of AGB and BGB were compiled from 1542 samples for communities across forests in China. Standardized major axis regression was conducted to examine whether AGB and BGB were allocated isometrically or allometrically at a community level. Redundancy analysis was used to analyze the relationships of BGB/AGB ratio with climatic factors and soil properties.Important findings We found that the slopes of the relationship between logAGB and logBGB were not always comparable to 1.0 (isometric allocation) at community levels, including primary forest, secondary forest, and planted forest. Meanwhile, samples in clay, loam, and sand soil types also presented the same phenomenon. Furthermore, the radically different allocations of AGB and BGB were found in northern and southern China. Environmental factors totally explained 3.86% of the variations in the BGB/AGB ratio at the community level, which include the mean annual precipitation, mean annual temperature, potential water deficit index, soil carbon content, soil nitrogen content, soil clay, soil loam, soil sand, soil pH, and soil bulk density. In addition, the environmental factors also have effects on the BGB/AGB ratio in other categories. The patterns revealed in this study are helpful for better understanding biomass partitioning and spreading the carbon circle models.     

Contribution of Old Growth Forests to the Carbon Budget of the Boreal Zone in Central Siberia

Old growth (mature and overmature) forests of Central Siberia accumulate carbon not only in the biomass but also in the phytodetritus, including in coarse woody debris (CWD), due to the slow seasonally depressed decomposition of organic matter. Slowly decomposing and accumulating on the soil surface stock of CWD, as a soil humus, serves as a long-term carbon pool in boreal forest ecosystems.     

Microbial biomass and growth kinetics of microorganisms in chernozem soils under different farm land use modes

The carbon content of microbial biomass and the kinetic characteristics of microbial respiration response to substrate introduction have been estimated for chernozem soils of different farm lands: arable lands used for 10, 46, and 76 years, mowed fallow land, non-mowed fallow land, and woodland. Microbial biomass and the content of microbial carbon in humus (Cmic/Corg) decreased in the following order: soils under forest cenoses-mowed fallow land-10-year arable land-46- and 75-year arable land. The amount of microbial carbon in the long-plowed horizon was 40% of its content in the upper horizon of non-mowed fallow land. Arable soils were characterized by a lower metabolic diversity of microbial community and by the highest portion of microorganisms able to grow directly on glucose introduced into soil. The effects of different scenarios of carbon sequestration in soil on the reserves and activity of microbial biomass are discussed.